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In mathematics, E-functions are a type of power series that satisfy particular arithmetic conditions on the coefficients. They are of interest in transcendence theory, and are more special than G-functions.

Definition

A function f(x) is called of type E, or an E-function,^[1] if the power series

f(x)=\sum _{n=0}^{\infty }c_{n}{\frac {x^{n}}{n!}}

satisfies the following three conditions:

All the coefficients c_n belong to the same algebraic number field, K, which has finite degree over the rational numbers;
For all ε > 0,

{\overline {\left|c_{n}\right|}}=O\left(n^{n\varepsilon }\right)

,

where the left hand side represents the maximum of the absolute values of all the algebraic conjugates of c_n;

For all ε > 0 there is a sequence of natural numbers q₀, q₁, q₂,... such that q_nc_k is an algebraic integer in K for k=0, 1, 2,..., n, and n = 0, 1, 2,... and for which

q_{n}=O\left(n^{n\varepsilon }\right)

.

The second condition implies that f is an entire function of x.

Uses

E-functions were first studied by Siegel in 1929.^[2] He found a method to show that the values taken by certain E-functions were algebraically independent.This was a result which established the algebraic independence of classes of numbers rather than just linear independence.^[3] Since then these functions have proved somewhat useful in number theory and in particular they have application in transcendence proofs and differential equations.^[4]

The Siegel–Shidlovsky theorem

Perhaps the main result connected to E-functions is the Siegel–Shidlovsky theorem (also known as the Shidlovsky and Shidlovskii theorem), named after Carl Ludwig Siegel and Andrei Borisovich Shidlovskii.

Suppose that we are given n E-functions, E₁(x),...,E_n(x), that satisfy a system of homogeneous linear differential equations

y_{i}^{\prime }=\sum _{j=1}^{n}f_{ij}(x)y_{j}\quad (1\leq i\leq n)

where the f_ij are rational functions of x, and the coefficients of each E and f are elements of an algebraic number field K. Then the theorem states that if E₁(x),...,E_n(x) are algebraically independent over K(x), then for any non-zero algebraic number α that is not a pole of any of the f_ij the numbers E₁(α),...,E_n(α) are algebraically independent.

Examples

Any polynomial with algebraic coefficients is a simple example of an E-function.
The exponential function is an E-function, in its case c_n=1 for all of the n.
If λ is an algebraic number then the Bessel function J_λ is an E-function.
The sum or product of two E-functions is an E-function. In particular E-functions form a ring.
If a is an algebraic number and f(x) is an E-function then f(ax) will be an E-function.
If f(x) is an E-function then the derivative and integral of f are also E-functions.

References

^ Carl Ludwig Siegel, Transcendental Numbers, p.33, Princeton University Press, 1949.
^ C.L. Siegel, Über einige Anwendungen diophantischer Approximationen, Abh. Preuss. Akad. Wiss. 1, 1929.
^ Alan Baker, Transcendental Number Theory, pp.109-112, Cambridge University Press, 1975.
^ Serge Lang, Introduction to Transcendental Numbers, pp.76-77, Addison-Wesley Publishing Company, 1966.

Weisstein, Eric W. "E-Function". MathWorld.

[1] Carl Ludwig Siegel, Transcendental Numbers, p.33, Princeton University Press, 1949.

[2] C.L. Siegel, Über einige Anwendungen diophantischer Approximationen, Abh. Preuss. Akad. Wiss. 1, 1929.

[3] Alan Baker, Transcendental Number Theory, pp.109-112, Cambridge University Press, 1975.

[4] Serge Lang, Introduction to Transcendental Numbers, pp.76-77, Addison-Wesley Publishing Company, 1966.

[1]

[2]

[3]

[4]

@@ Line 14: / Line 14: @@
 :<math>\overline{\left|c_{n}\right|}=O\left(n^{n\varepsilon}\right)</math>,
 where the left hand side represents the maximum of the absolute values of all the [[Conjugate element (field theory)|algebraic conjugates]] of ''c<sub>n</sub>'';
-* For all ε&nbsp;&gt;&nbsp;0 there is a sequence of natural numbers ''q''<sub>0</sub>, ''q''<sub>1</sub>, ''q''<sub>2</sub>,… such that ''q<sub>n</sub>c<sub>k''</sub> is an [[algebraic integer]] in ''K'' for ''k''=0, 1, 2,…, ''n'', and ''n'' = 0, 1, 2,… and for which
+* For all ε&nbsp;&gt;&nbsp;0 there is a sequence of natural numbers ''q''<sub>0</sub>, ''q''<sub>1</sub>, ''q''<sub>2</sub>,... such that ''q<sub>n</sub>c<sub>k''</sub> is an [[algebraic integer]] in ''K'' for ''k''=0, 1, 2,..., ''n'', and ''n'' = 0, 1, 2,... and for which
 :<math>q_{n}=O\left(n^{n\varepsilon}\right)</math>.
@@ Line 21: / Line 21: @@
 ==Uses==
-''E''-functions were first studied by [[Carl Ludwig Siegel|Siegel]] in 1929.<ref>C.L. Siegel, ''Über einige Anwendungen diophantischer Approximationen'', Abh. Preuss. Akad. Wiss. '''1''', 1929.</ref>  He found a method to show that the values taken by certain ''E''-functions were [[algebraically independent]].This was a result which established the algebraic independence of classes of numbers rather than just linear independence.<ref>Alan Baker, ''Transcendental Number Theory'', pp.109-112, Cambridge University Press, 1975.</ref> Since then these functions have proved somewhat useful in [[number theory]] and in particular they have application in [[Transcendental numbers|transcendence]] proofs and [[differential equations]].<ref>Serge Lang, ''Introduction to Transcendental Numbers'', pp.76-77, Addison-Wesley Publishing Company, 1966.</ref>
+''E''-functions were first studied by [[Carl Ludwig Siegel|Siegel]] in 1929.<ref>C.L. Siegel, ''Über einige Anwendungen diophantischer Approximationen'', Abh. Preuss. Akad. Wiss. '''1''', 1929.</ref>  He found a method to show that the values taken by certain ''E''-functions were [[algebraically independent]].This was a result which established the algebraic independence of classes of numbers rather than just linear independence.<ref>Alan Baker, ''Transcendental Number Theory'', pp.109-112, Cambridge University Press, 1975.</ref> Since then these functions have proved somewhat useful in [[number theory]] and in particular they have application in [[Transcendental numbers|transcendence]] proofs and [[differential equations]].<ref>[[Serge Lang]], ''Introduction to Transcendental Numbers'', pp.76-77, Addison-Wesley Publishing Company, 1966.</ref>
 ==The Siegel–Shidlovsky theorem==
@@ Line 27: / Line 27: @@
 Perhaps the main result connected to ''E''-functions is the Siegel–Shidlovsky theorem (also known as the Shidlovsky and Shidlovskii theorem), named after [[Carl Ludwig Siegel]] and Andrei Borisovich Shidlovskii.
-Suppose that we are given ''n'' ''E''-functions, ''E''<sub>1</sub>(''x''),…,''E''<sub>''n''</sub>(''x''), that satisfy a system of homogeneous linear differential equations
+Suppose that we are given ''n'' ''E''-functions, ''E''<sub>1</sub>(''x''),...,''E''<sub>''n''</sub>(''x''), that satisfy a system of homogeneous linear differential equations
 :<math>y^\prime_i=\sum_{j=1}^n f_{ij}(x)y_j\quad(1\leq i\leq n)</math>
-where the ''f<sub>ij</sub>'' are rational functions of ''x'', and the coefficients of each ''E'' and ''f'' are elements of an algebraic number field ''K''.  Then the theorem states that if ''E''<sub>1</sub>(''x''),…,''E''<sub>''n''</sub>(''x'') are algebraically independent over ''K''(''x''), then for any non-zero algebraic number α that is not a pole of any of the ''f<sub>ij</sub>'' the numbers ''E''<sub>1</sub>(α),…,''E''<sub>''n''</sub>(α) are algebraically independent.
+where the ''f<sub>ij</sub>'' are rational functions of ''x'', and the coefficients of each ''E'' and ''f'' are elements of an algebraic number field ''K''.  Then the theorem states that if ''E''<sub>1</sub>(''x''),...,''E''<sub>''n''</sub>(''x'') are algebraically independent over ''K''(''x''), then for any non-zero algebraic number α that is not a pole of any of the ''f<sub>ij</sub>'' the numbers ''E''<sub>1</sub>(α),...,''E''<sub>''n''</sub>(α) are algebraically independent.
 ==Examples==